Saliva-based methods for SARS-CoV-2 testing in low- and middle-income countries

Abstract As the coronavirus disease 2019 (COVID-19) continues to disproportionately affect low- and middle-income countries, the need for simple, accessible and frequent diagnostic testing grows. In lower-resource settings, case detection is often limited by a lack of available testing for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). To address global inequities in testing, alternative sample types could be used to increase access to testing by reducing the associated costs. Saliva is a sensitive, minimally invasive and inexpensive diagnostic sample for SARS-CoV-2 detection that is appropriate for asymptomatic surveillance, symptomatic testing and at-home collection. Saliva testing can lessen two major challenges faced by lower- and middle-income countries: constrained resources and overburdened health workers. Saliva sampling enables convenient self-collection and requires fewer resources than swab-based methods. However, saliva testing for SARS-CoV-2 diagnostics has not been implemented on a large scale in low- and middle-income countries. While numerous studies based in these settings have demonstrated the usefulness of saliva sampling, there has been insufficient attention on optimizing its implementation in practice. We argue that implementation science research is needed to bridge this gap between evidence and practice. Low- and middle-income countries face many barriers as they continue their efforts to provide mass COVID-19 testing in the face of substantial inequities in global access to vaccines. Laboratories should look to replicate successful approaches for sensitive detection of SARS-CoV-2 in saliva, while governments should act to facilitate mass testing by lifting restrictions that limit implementation of saliva-based methods.


Introduction
In 2020, the Africa Centres for Disease Control and Prevention aimed to increase testing for severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) from 1300 per million to 16 000 per million population. 1 They surpassed their goal; by early 2022, over 95 million tests had been performed (about 74 000 tests per million people). 2 Nonetheless, only one in seven coronavirus disease 2019 (COVID- 19) infections were detected in Africa in 2021. 3 Inadequate community-based testing has likely resulted in thousands of preventable COVID-19-related deaths. 4 With case detection limited by the low availability of testing, the full extent of COVID-19-related morbidity and mortality in low-and middle-income countries may only later be revealed. 5 Large-scale diagnostic capacity in lower-and middleincome countries is impeded by the scarcity of biosafetyequipped laboratories to handle samples; the high costs of test materials; the lack of specialized technicians to perform polymerase chain reaction (PCR) assays; and the shortage of trained health professionals to collect nasopharyngeal swab samples. 6 Low-and middle-income countries also face persistent inequitable access to COVID-19 vaccines -a situation that has been described as vaccine apartheid. 7 By August 2022, almost 80% of adults in high-income nations had received at least one dose of vaccine. 8 In contrast, only around 20% of those in low-income countries have received at least one dose. 8 These overlapping inequities in vaccine accessibility and testing availability must be addressed.
Even as vaccination rates slowly climb in low-and middle-income countries, the need for testing remains high. 9 A simple, accessible testing strategy is necessary for disease surveillance, enabling public health systems to assess infection prevalence and detect the emergence of variants to prevent further dissemination of the virus. 10 Moreover, there is a moral imperative to support communities where vaccine availability and access are low. Organizations and government agencies across the globe, especially those of high-income nations, must collaborate to ensure that low-and middle-income countries can access sufficient testing and vaccination resources.
Saliva-based methods can reduce the cost and improve scalability and sustainability of testing programmes in low-and middle-income countries. Saliva has similar effectiveness to nasopharyngeal swabs for detecting SARS-CoV-2, 11 while also detecting early infection with greater sensitivity than anterior nasal 12,13 and mid-turbinate swabs. 14 This finding has remained true following the rise and worldwide spread of the Omicron variant of SARS-CoV-2. 15, 16 We discuss here how saliva testing mitigates two major challenges for lower-and middle-income countries: constrained resources and overburdened health workers.

Test affordability
Swab-based testing approaches are costly and resourceintensive. 17 In low-and middle-income countries, the cost of swab-based COVID-19 PCR testing can be more than 200 United States dollars (US$). 18 A single test can cost up to 25% (US$ 210) of the U$ 858 gross domestic product (GDP) SARS-CoV-2 testing in low-and middle-income countries Steph H Tan et al.
per capita in Uganda or 40% (US$ 210) of the US$ 517 GDP per capita in Afghanistan. 19 While provided at no cost to individuals in some low-and middleincome countries, 18 testing remains inaccessible to many.
Saliva-based testing approaches are comparatively less costly. As saliva specimens are stable without preservatives and cold-chain management, they do not require expensive, specialized collection tubes. 20 Saliva-based testing also does not require highly trained health workers, specialized swab supplies or personal protective equipment. The authors of a meta-analysis estimated that saliva collection saves US$ 633 000 for every 100 000 people sampled compared with nasopharyngeal swabs. 21 Additionally, saliva can be self-collected at clinics and testing centres, thus minimizing discomfort for patients. The method also reduces the risk of occupational exposure to infection for health-care providers, 21 a particular benefit in lowerand middle-income countries, which have fewer health workers per capita relative to high-income countries. 22 Selfcollection at home can further decrease the human resources needed at testing centres, avoid the need for people to travel and wait at potentially crowded facilities, and reduce the potential for further COVID-19 spread.
Self-collection of saliva is not equivalent to self-testing. Samples may be self-collected under supervision at a testing centre or unsupervised at home to be submitted for laboratory testing. In contrast, self-testing for COVID-19 involves the individual producing their own test result, predominantly using a rapid antigen test. 23 While these tests can be performed anywhere, including at home, there is no requirement to report the results to health authorities. Although the widespread availability of rapid antigen tests has greatly relieved the pressure on testing sites in highincome settings, the method has led to gaps in the data on the true number of COVID-19 cases. 24 Thus, self-testing does not contribute to national CO-VID-19 monitoring and surveillance, whereas self-collection of samples does. Self-collection of saliva remains important to safely expanding a country's testing efforts.
Another resource-saving approach is the use of methods which bypass the ribonucleic acid (RNA) extraction step (also known as a direct testing approach). These methods have rarely been explored for nasal swabs but are widely validated on saliva samples in large-scale testing programmes. [25][26][27] For example, the Philippine Red Cross launched a saliva-based mass testing programme, providing PCR tests without using RNA extraction 27 at less than half the cost of other reverse transcription (RT)-PCR tests. 28 These efforts have enabled more affordable and, importantly, more sustainable testing programmes that have effectively controlled outbreaks. 11,29 Current applications SARS-CoV-2 saliva testing studies and programmes have been implemented in most regions of the world, including low-cost and less technologically demanding methods that can be adapted to low-resource settings. 29 Low-and middle-income countries globally have demonstrated the feasibility of salivabased diagnostics with PCR technology. 29 In South America, saliva collection has been recommended as a highperforming, non-invasive option. The sensitivity of the method was found to be comparable to that of nasopharyngeal swabs in studies in Brazil, 30 Chile 31 and French Guiana. 32 In South-East Asia, saliva-based testing is considered to be suitable for low-resource areas and able to accurately detect asymptomatic infections through PCR screening, as demonstrated in Viet Nam. 33 In sub-Saharan Africa, saliva-based PCR testing is offered in several countries, including the Democratic Republic of the Congo and Sudan, while a self-collection programme is currently being piloted in South Africa. 29 Saliva sampling also allows for sample pooling in laboratories, as several samples can be tested using one reaction. Therefore, the method substantially increases test throughput while reducing the financial and time costs associated with PCR testing. 34 Pooled saliva testing protocols for SARS-CoV-2 have proven effective in numerous settings globally, such as schools and workplaces in Mexico 35 and Thailand. 36 Pooling of samples allows institutions to more rapidly assess infection status and adjust prevention measures as necessary, generating reliable and long-lasting testing programmes that support individuals' returning to places of work and study. 29,37 Loop-mediated isothermal amplification (LAMP) is an alternative diagnostic tool to PCR for low-and middle-income countries because it requires fewer resources, including highly trained laboratory personnel. LAMP is a method that can be used in both laboratory and field conditions, and is compatible with saliva testing. 38 Saliva-based LAMP can deliver rapid and reliable SARS-CoV-2 test results using simple equipment and processes, involving only a heat block and a single fluid transfer step. 39 In middle-income countries, LAMP-based testing of saliva was highly sensitive compared with nasopharyngeal swabs in studies in Brazil (78.9%; 60/76 samples), 40 in China (97.0%; 65/67 samples) 41 and in Mexico (100.0%; 25/25 samples). 42 This approach was also an attractive solution when testing options, including government programmes, were scarce in Nicaragua, 29 where a high prevalence of infection (122/402 people tested; 30.4%) was detected in healthcare workers. 43 The potential for salivabased LAMP has been demonstrated at scale in the United Kingdom of Great Britain and Northern Ireland, where 86 760 saliva samples underwent direct RT-LAMP. 44 The method bypasses RNA extraction, demonstrating a sensitivity of 84.6% (209/247 samples) compared with PCR. 44 Additionally, in the United States of America a workplace surveillance programme using a LAMP method (validated to be 97.0% sensitive; 29/30 samples) tested over 30 000 self-collected saliva samples from 755 individuals in 12 months. 45 Relative to approaches that require laboratory processing, rapid antigen testing is convenient and inexpensive. Thus, rapid antigen tests are now widespread. For example, in Thailand, the government authorized 63 at-home saliva-based rapid antigen tests (as of early 2022). Rapid antigen tests are also being used for surveillance in Uganda. 29 However, they are 30.0-40.0% less sensitive than PCR tests. 46 Moreover, the results of rapid antigen tests taken at home are unlikely to be reported to public health authorities, thus limiting efforts to assess community transmission.
Point-of-care testing platforms could also facilitate rapid, convenient SARS-CoV-2 testing. 47 Point-of-care platforms are already widely used in low-and middle-income countries for the diagnosis of human immunodefi-  50 A saliva-based point-of-care testing innovation has also been developed in Türkiye, where an electrochemical immunoassay was developed to enable reliable detection of the SARS-CoV-2 spike S1 protein using a portable device. 51 Overall, these findings highlight the potential for simplified molecular testing approaches in low-and middleincome countries.

Improving testing coverage
Dependence on external suppliers and expertise, and competition with higher-income nations for testing resources, has limited the expansion of COVID-19 testing programmes in many low-and middle-income countries. 1 A less resource-intensive sample type with multiple uses could reduce the coverage gap between lower-and higher-resource countries. Saliva reduces reliance on swabs and other specialized resources, making it a more sustainable option in many settings. Existing workforces and laboratories can be trained to handle saliva through internet-accessible instructions on saliva sample collection and processing. Crucially, a single saliva sample can simultaneously identify active COV-ID-19 cases (through SARS-CoV-2 RNA detection) and antibodies that are either vaccine-induced or produced from prior SARS-CoV-2 exposure. 11 Although serosurveys to monitor COVID-19 burden have been explored in low-and middleincome countries, 52 saliva is a more convenient sample type that can improve the participation and sustainability of such surveillance programmes. Saliva is less financially burdensome and invasive than the traditional route of requiring a nasopharyngeal swab to detect active infection status or drawing blood for determination of antibody status. 53 Saliva collection also requires a fraction of the resources needed for drawing blood for antibody detection and can circumvent peoples' aversion to testing involving needles. Widespread HIV screening in low-and middle-income countries has demonstrated that saliva testing is more acceptable to patients and health workers than serological testing. 54 With growing support for the use of saliva for SARS-CoV-2 antibody detection, 55 and given the acceptability of saliva for HIV screening in lower-and middleincome countries, saliva sampling could improve the affordability and acceptability of antibody testing. Thus, saliva sampling for detection of anti-SARS-CoV-2 antibodies could fill testing gaps while allowing population immunity to be monitored. 56 Combined information on acute and previous SARS-CoV-2 infections is essential for monitoring local outbreaks, determining the proportion of asymptomatic COVID-19 cases and guiding risk mitigation decisions by policy-makers.
Although this new approach is promising, designers of saliva-based COVID-19 testing strategies must be sensitive to the potential impact of such methods on other public health programmes in low-resource settings. Repurposing laboratory facilities for COVID-19 testing can interrupt other essential diagnostic services, including those for HIV, tuberculosis and malaria. 1 For the first time in a decade, tuberculosis deaths increased in 2020 due to reduced access to diagnostic testing and treatment amidst the COVID-19 pandemic. 57 Without vigilance, widespread implementation of saliva sampling in low-and middle-income countries could inadvertently disrupt existing medical goods supply chains. For example, if sputum collection containers essential to tuberculosis programmes are diverted to collect saliva samples for COVID-19 testing, timely evaluation of tuberculosis could be compromised. 58 Ideally, SARS-CoV-2 testing strategies should supplement or be integrated with existing programmes, such as through multiplexing (a laboratory technique that enables the identification of multiple targets in a single diagnostic procedure).

Discussion
Ultimately, simple, inexpensive and accessible methods of sample collection are critical to expanding and sustaining COVID-19 testing capabilities in lowand middle-income countries. Saliva is simple to self-collect, and the supply chains for mass testing strategies are easier than conventional sample types to establish and sustain. A large body of work has demonstrated that saliva can be a sensitive sample type for SARS-CoV-2 detection and is feasible in lowand middle-income countries.
Wider adoption of saliva as a sample type may be cost-effective as well. In addition to the savings compared with nasopharyngeal swabs, saliva is an ideal sample type for multiplexing. For example, low-cost methods developed for SARS-CoV-2 can be expanded using multiplexing. Saliva-based PCR multiplex approaches enable the noninvasive, simultaneous detection of multiple diseases in a single assay. Consequently, saliva tests could be used to detect and differentiate SARS-CoV-2 RNA from other respiratory pathogens, such as influenza A and B, 59 and primary pathogens that are endemic in lowerand middle-income countries including HIV, 60 tuberculosis 61 and malaria. 62 Multiplexing could also mitigate the potential interference of COVID-19 testing services with other essential health-care and diagnostic services, such as for tuberculosis and other infectious diseases.
The evidence base for saliva as a reliable and cost-effective sample type for SARS-CoV-2 diagnostics and surveillance is strong and continues to grow. 11 Nevertheless the adoption, fidelity and sustainability 63 of saliva-based testing in low-and middle-income countries will depend on the quality of its implementation. When evidence-based practices are transferred to new settings, barriers to implementation can reduce their ef-SARS-CoV-2 testing in low-and middle-income countries Steph H Tan et al.
fectiveness in practice. Implementation science offers systematic approaches to bridging the gap between evidence and practice. Such an approach is needed to optimize delivery of saliva-based COVID-19 testing for low-and middleincome countries. There is immense promise for saliva testing in poorer countries; implementation science can help realize this promise.
With each day, the cooperation between higher and lower income na-tions to support parallel testing and vaccination efforts becomes more pressing. Low-and middle-income countries face many barriers as they continue to provide mass testing in the face of large inequities in global access to vaccines. Saliva sampling can mitigate some of these barriers by reducing the demand on human and material resources. Laboratories should look to replicate successful approaches for sensitive detection of SARS-CoV-2 in saliva, while governments should act to facilitate mass testing by lifting restrictions that limit implementation of these promising methods. ■ Acknowledgements ALW and MAH contributed equally to the study and should be recognized as co-senior authors.